System for Programming Domestic Appliances and Method for Programming Assembly-Line Programmable Domestic Appliances

ABSTRACT

The present invention relates to a system for programming domestic appliances and a method for programming assembly-line programmable domestic appliances, especially a system wherein programming occurs without the physical connection between a transmission unit and a reprogrammable processor present in a processing unit integrated into the domestic appliance. The system for programming domestic appliances comprises a remote programming unit (UR) and a reprogrammable processor (PR) present in a processing unit (UP) integrated into the domestic appliance (E N ), the remote programming unit (UR) being provided with a data transmission device (T UR ) and the reprogrammable processor (PR) present in a processing unit (UP) being provided with a data receiving device (R UP ), and the data transmission and reception devices (T UR , R UP ) are based on a magnetic field. The remote programming unit (UR) is loaded with at least one program code (S N ) to be transmitted by the data transmission device (T UR ) of the remote programming unit (UR) to the reprogrammable processor (PR) present in the processing unit (UP) of the domestic appliance (E N ). A method for programming assembly-line programmable domestic appliances is also disclosed, which is applicable to control the system object of the present invention.

The present invention relates to a system for programming domesticappliances and a method for programming assembly-line programmabledomestic appliances, especially a system wherein programming occurswithout the physical connection between a transmission unit and areprogrammable processor integrated into the domestic appliance.

DESCRIPTION OF THE PRIOR ART

The programming of reprogrammable processors in the production line orin the field where the appliance is located during use, is currentlyimplemented by means of the physical contact of a set of needlesexisting in the programming equipment, which touch specific points ofthe electronic circuit containing the reprogrammable processor.

Another technique comprehends physical contact between a connector ofthe programming equipment and a connector positioned at the electroniccircuit containing the reprogrammable processor. These two techniqueshave the disadvantage of requiring a physical connection between theprogramming equipment and the electronic control.

A third technique consists of the manual choice of configurations in aset of mechanical selection devices, such as resistors and dip switches,located in the electronic control. This procedure is disadvantageousbecause requires physical contact between the operator that makes theconfiguration and the mechanical selection devices.

In the two last techniques mentioned, it is quite common that thephysical contact requires the removal of screws and actuation inmechanical locks, disassembly of plastic parts and disengagement ofconnections, to enable access to the electronic circuit, making thelarge scale production process more expensive and with lower quality.

Another alternative is the use of previously recorded processors, withthe disadvantage of not allowing changes in their configuration. Anothertechnique is programming domestic devices without the physicalconnection, for instance, making use of infrared or electromagneticwaves. An example of this type of solution is found in documentEP1544827, which discloses a wireless communication system forcentralized programming of domestic appliances. This system, however,does not foresee the possibility of carrying out the domestic applianceprogramming in the production line, nor does it anticipate thepossibility of using magnetic field programming, therefore, beingsusceptible to the interference of an electromagnetic field that mayaffect the equipment.

BRIEF DESCRIPTION AND OBJECTIVES OF THE INVENTION

The present invention has as its objective a system and method forprogramming reprogrammable processors, composed of an electronic controlhaving at least one remote programming unit provided with a datatransmission device; and one reprogrammable processor, located in adomestic appliance provided with a data receiving device, thesetransmission and reception devices transmitting program codes through awireless connection using a magnetic field-based transmission means.

During the process of producing domestic appliances, the electroniccontrols containing embedded processors may be basically of two types:fixed programming or reprogrammable.

In the case of electronic controls with fixed programming, anassociation must be established between the domestic appliance model andthe electronic control model suitable for this equipment. This situationhas the disadvantage of requiring high stock management in order toavoid errors and reprocessing.

In the case of reprogrammable electronic controls, the situation may bedivided into two groups: with physical contact between the programmingdevice and the equipment to be programmed and without physical contactbetween these elements. The solutions with physical contact have thedisadvantages of commonly presenting inefficient electric contacts ordamage caused by operator's handling and in some cases requiring thedisassembly of equipment parts, reducing quality and burdening theproductive process.

On the other hand, the solution without physical contact is normallymade by infrared or electromagnetic waves. The infrared technique hasthe disadvantage of requiring visual access between the programmingdevice and the equipment being programmed. The use of electromagneticwaves is disadvantageous not only because it is susceptible to theinfluence of interferences that may generate difficulties in datatransmission or even cause inappropriate programming but also because itrequires higher cost electronic components that operate in highfrequency.

The system and method proposed herein, based on a magnetic field with areceiver circuit tuned to low frequency and with a low amplificationgain stage, is free from the disadvantages found in the abovementionedtechniques.

A simple, low-cost electronic receiver circuit is used, which may thusbe added to each product unit produced in large scale. This receivercircuit has a resonating inductor-capacitor structure, which senses thepresence of a magnetic field generating an induced voltage. At theresonating frequency, this voltage has maximum amplitude. Acommon-emitter configuration amplifier stage receives this inducedvoltage, amplifies it and makes it available to a rectification andfiltering circuit, which eliminates the high-frequency component. Atlast, a voltage equalization stage receives the induced signal that wastreated by the previous stages, generating voltage values suitable forprocessors' digital inputs.

These objects are achieved by means of a system for programming domesticappliances comprising a remote programming unit and a processing unitintegrated into the domestic appliance which contains a reprogrammableprocessor, the remote programming unit being provided with a datatransmission device, and the processing unit containing thereprogrammable processor being provided with a data receiving device,these transmission and reception devices being based on a magneticfield, and the remote programming unit being loaded with at least oneprogram code to be transmitted by the data transmission device of theremote programming unit to the data receiving device of the processingunit containing the domestic appliance reprogrammable processor.

The objects of the present invention are further achieved by means of amethod for programming assembly-line programmable domestic appliances,characterized in that it is applicable to a system comprising a remoteprogramming unit and a reprogrammable processor provided in a processingunit integrated into the domestic appliance, said method comprising thesteps of loading the remote programming unit with at least one programcode from a program code library and transmitting data of the programcode(s) to the reprogrammable processor of the processing unit through amagnetic field as a plurality of domestic appliances is passed on frontof the remote programming unit.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will be further described in more details based onone example of embodiment represented in the drawings. The figures show:

FIG. 1 represents an electronic circuit of the data receiving deviceaccording to one of the embodiments of the present invention; and

FIG. 2 is a schematic drawing of the domestic appliance programmingsystem in the production line, which is the object of the presentinvention.

DETAILED DESCRIPTION OF DRAWINGS

As may be seen in FIGS. 1 and 2, the domestic appliance programmingsystem, object of the present invention, comprises a remote programmingunit UR and a reprogrammable processor PR that is integrated into thedomestic appliance E_(N).

As may be seen in FIG. 2, the remote programming unit UR is providedwith a data transmission device T_(UR), and each one of the processingunits UP contains one or more reprogrammable processors PR connected toa data receiving device R_(UP), the data transmission and receptiondevices (T_(UR), R_(UP)) being based on magnetic field.

The system further provides a library S_(LIB), which stores severalprogram codes S_(N) that can be transmitted by the remote programmingunit UR to the reprogrammable processor PR of the processing unit UPthrough the data transmission and reception devices (T_(UR), R_(UP)).

In this sense, it is possible, for instance, that one or more of theseveral program codes S₁, S₂ . . . S_(N) of library S_(LIB) is loadedinto the remote programming unit UR, which can transmit these codes tothe reprogrammable processor PR of the processing unit UP, for example,during the manufacture of the domestic appliance or even after itsmanufacture, so that the program code S_(N) is updated, when needed.FIG. 2 schematically illustrates that domestic appliances E₁, E₂, E₃ . .. E_(N) may be programmed at the assembly line phase, only bypositioning the remote programming unit UR properly.

With regard to the configuration of the data transmission and receptiondevices (T_(UR), R_(UP)), these are based on a magnetic field,considering the advantages that this type of transmission brings to thepresent invention be seen in FIG. 1, one embodiment of the datareceiving device R_(UP) provides a topology comprising a passive circuitsensitive to magnetic fields 11 and an active circuit for the treatmentof signals 234, the active circuit for the treatment of signals 234being responsible for converting the electric signals provided by thepassive circuit sensitive to magnetic fields 11 into electric signalscompatible with the reprogrammable processor PR of the processing unitUP.

The passive circuit sensitive to magnetic fields 11 comprises aresonating inductor-capacitor topology being composed of inductor L₁ andcapacitor C₁, configured to be tuned to low frequency and, morepreferably, to the frequency range of 1 kHz to 530 kHz.

The syntony of the circuit sensitive to magnetic fields 11 of the datareceiving device R_(UP) is particularly advantageous in the presentapplication, because the magnetic field has a rapidly decayingintensity, at the ratio of:

${decay} = \frac{1}{d^{3}}$

Hence, the circuit sensitive to magnetic field 11 of the data receivingdevice R_(UP) has a typical sensitivity of only up to 10 cm, making itresistant against the influence of electromagnetic waves, because theseact at a higher frequency range, considering that, for tuning anelectromagnetic wave to low frequency, the antenna would have to besized in kilometers, which is unfeasible in practice.

The active circuit for the treatment of signals 234 comprises anamplification stage in the common-emitter configuration 12 composed of atransistor Q₁, resistors R₁, R₂, R₃ and R₄ and capacitor C₃; arectification and filtering stage 13 composed of a diode D₁, resistor R₅and capacitor C₄ to convert the signal read in the data receiving deviceR_(UP) at DC level and further cut off the high frequencies; and anequalization stage of voltage levels 14 composed of a transistor Q₂ andresistors R₆ and R₇, which is configured to work with the cut-off andsaturation of transistor Q₂, so as to have logic level 1 or 0 as inputfor the reprogrammable processor PR of the processing unit UP.

Furthermore, the active circuit for the treatment of signals 234 shouldbe configured to have low amplification gain and, preferably, to have anamplification gain in a range of 10 to 20.

With the configuration presented in the system of the present invention,the objects of the invention are achieved since the cited configurationhas a low-cost system and eliminates wired connections, uses a dipswitch, eliminates the risks of interference by electromagnetic signalsand is able to effectively program domestic appliances in the productionline or afterwards.

With regard to the methodology to control the system object of thepresent invention, the following steps should be foreseen, especially incase of programming assembly-line programmable domestic appliances. Thesteps comprise:

-   -   loading the remote programming unit UR with at least one program        code S_(N) from a library of program codes S_(N);    -   transmitting data of the program code(s) S_(N) through a        magnetic field to a reprogrammable processor PR of the        processing unit UP as a plurality of domestic appliances E_(N)        is passed on front of the remote programming unit UR.

Thus, it is possible to program large quantities of domestic appliancesE_(N) in a fast and cheap manner.

Furthermore, it is possible to foresee that the data transmission andreception devices (T_(R), R_(UP)) will operate both ways in order notonly to program the domestic appliances E_(N) but also receive statusinformation.

Having described examples of the invention with reference to itspreferred embodiments, it is to be understood that the scope of thepresent invention embraces other possible variations, being limitedsolely by the appended claims, including the possible equivalentstherein.

1. A system for programming domestic appliances during manufacturingprocess, characterized by comprising: a remote programming unit (UR);and a processing unit (UP) integrated into the domestic appliance(E_(N)) containing a reprogrammable processor (PR); the remoteprogramming unit (UR) being provided with a data transmission device(T_(UR)); and the processing unit (UP) containing the reprogrammableprocessor (PR) being provided with a data receiving device (R_(UP)); thedata transmission (T_(UR)) and reception (R_(UP)) devices being based ona magnetic field; and the remote programming unit (UR) being loaded withat least one program code (S_(N)) to be wirelessly transmitted by thedata transmission device (T_(UR)) of the remote programming unit (UR) tothe data receiving device (R_(UP)) of the processing unit (UP)containing the reprogrammable processor (PR) of the domestic appliance(E_(N)), the remote programming unit (UR) being configured to transmitthe program code (S_(N)) at the assembling line as a plurality ofdomestic appliances (E_(N)) is passed in front of it.
 2. A system forprogramming domestic appliances according to claim 1, characterized inthat the data receiving device (R_(UP)) is comprised by a passivecircuit sensitive to magnetic fields (11) and an active circuit for thetreatment of signals (234), the active circuit for the treatment ofsignals (234) converting the electric signals provided by the passivecircuit sensitive to magnetic fields (11) into electric signalscompatible with the reprogrammable processor (PR) of the processing unit(UP).
 3. A system for programming domestic appliances according to claim2, characterized in that the passive circuit sensitive to magneticfields (11) comprises a resonating inductor-capacitor topology.
 4. Asystem for programming domestic appliances according to claim 2,characterized in that the active circuit for the treatment of signals(234) comprises an amplification stage in the common-emitterconfiguration (12), a rectification and filtering stage (13) and anequalization stage of the voltage levels (14).
 5. A system forprogramming domestic appliances according to claim 3, characterized inthat the passive circuit sensitive to magnetic fields (11) is configuredto be tuned to low frequency.
 6. A system for programming domesticappliances according to claim 5, characterized in that the passivecircuit sensitive to magnetic fields (11) is configured to be tuned tothe frequency range of 1 kHz to 530 kHz.
 7. A system for programmingdomestic appliances according to claim 4, characterized in that theactive circuit for the treatment of signals (234) is configured to havelow amplification gain.
 8. A system for programming domestic appliancesaccording to claim 7, characterized in that the active circuit for thetreatment of signals (234) is configured to have amplification gain in arange of 10 to
 20. 9. A method for programming assembly-lineprogrammable domestic appliances, characterized in that it is applicableto a system comprising a remote programming unit (UR); and areprogrammable processor (PR) provided in a processing unit (UP)integrated into the domestic appliance (E_(N)), said method comprisingthe steps of: loading the remote programming unit (UR) with at least oneprogram code (S_(N)) from a library of program codes (S_(LIB));transmitting data of the program code(s) (S_(N)) through a magneticfield to a reprogrammable processor (PR) of the processing unit (UP) asa plurality of domestic appliances (E_(N)) is passed on front of theremote programming unit (UR).
 10. A method according to claim 9,characterized in that the data transmission of the program code(s)(S_(N)) to the reprogrammable processor (PR) of the processing unit (UP)is done with a circuit tuned to low frequency.
 11. A method according toclaim 10, characterized in that the data transmission of the programcode(s) (S_(N)) to the reprogrammable processor (PR) of the processingunit (UP) is done with a circuit tuned to the frequency range of 1 kHzto 530 kHz.
 12. A method according to claim 9, characterized in that thedata transmission of the program code(s) (S_(N)) to the reprogrammableprocessor (PR) of the processing unit (UP) is done with lowamplification gain.
 13. A method according to claim 12, characterized inthat the data transmission of the program code(s) (S_(N)) to thereprogrammable processor (PR) of the processing unit (UP) is done withan amplification gain in a range of 10 to
 20. 14. A system forprogramming domestic appliances during manufacturing process,characterized by comprising: a remote programming unit (UR); and aprocessing unit (UP) integrated into the domestic appliance (E_(N))containing a reprogrammable processor (PR); the remote programming unit(UR) being provided with a data transmission device (T_(UR)); and theprocessing unit (UP) containing the reprogrammable processor (PR) beingprovided with a data receiving device (R_(UP)); the data transmission(T_(UR)) and reception (R_(UP)) devices being based on a magnetic field;and the remote programming unit (UR) being loaded with at least oneprogram code (S_(N)) to be wirelessly transmitted by the datatransmission device (T_(UR)) of the remote programming unit (UR) to thedata receiving device (R_(UP)) of the processing unit (UP) containingthe reprogrammable processor (PR) of the domestic appliance (E_(N)), theremote programming unit (UR) being configured to transmit the programcode (E_(N)) at the assembling line as a plurality of domesticappliances (E_(N)) is passed in front of it, the system being furthercharacterized in that the data receiving device (R_(UP)) is comprised bya passive circuit sensitive to magnetic fields (11) not sensitive toelectromagnetic waves, and an active circuit for the treatment ofsignals (234), the active circuit for the treatment of signals (234)converting the electric signals provided by the passive circuitsensitive to magnetic fields (11) into electric signals compatible withthe reprogrammable processor (PR) of the processing unit (UP), thepassive circuit (11) being configured to be tuned to low frequency.